Salivary epithelial-myoepithelial carcinoma: clinical, morphological and molecular features.

Epithelial-myoepithelial carcinoma (EMC) is a rare biphasic tumor accounting for less than 2% of all salivary gland malignancies. It presents as a slowly growing, asymptomatic small size mass, with ulceration of overlying mucosa in some cases. Microscopically, it is characterized by glands lined by the simultaneous presence of two different cell components, inner epithelial cells and outer myoepithelial cells. Immunohistochemical staining of myoepithelial cells is variably positive for vimentin, Smooth Muscle Actin (SMA), Muscle Specific Actin (MSA), S100, Smooth Muscle Myosin Heavy Chain I(SM-MHC), calponin and p63. Several molecular alterations, mainly point mutations, have been described. Mutations of HRAS, AKT1, CTNNB1 and PIK3CA were highlighted in variable percentage of EMC samples. EMC is considered a low-grade malignant tumor with a 5-year survival rate of 94% that may commonly recur locally after resection in 30-50% of cases. At the moment, adequate resection with negative margins is the minimum recommended and necessary treatment.

Prognostic value of cancer stem cells, epithelial-mesenchymal transition and circulating tumor cells in lung cancer.

The epithelial-mesenchymal transition (EMT) is a program involved in embryonic development that is often activated during cancer invasion and metastasis. CD133 is the main marker identifying cancer stem cells (CSCs) in lung cancer. Circulating tumor cells (CTCs) are demonstrated to be useful as a biomarker for the diagnosis and treatment of cancer. The aim of this study was to correlate EMT, CSCs and CTCs with patient prognosis to verify whether they can contribute to better stratification of lung cancer patients at risk for recurrent and metastatic disease. Pulmonary venous blood was drawn after major pulmonary surgery in 45 patients with resectable non-small cell lung cancer (NSCLC) in order to identify CTCs. For the same patients, we also constructed prognostic lung tissue microarrays (TMA) for CD133 and c-kit and evaluated CSC and EMT markers using flow cytometry. Cytokeratin-positive cells were detectable in 11 (23.9%) cases. c-kit expression was heterogeneous in prognostic TMAs while CD133 expression was low or absent which was also confirmed by flow cytometry and RT-PCR. Flow cytometric analysis showed that the mean percentage of cells with CD133 expression was 1.6%. CD90 and CD326 markers were co-expressed with a mean percentage of 10.41%. When CD133 and CD90/CD326 expression was correlated with follow-up, CD133 showed a higher correlation with deceased patients when compared with CD90/CD326 co-expression (32.5 vs. 9.5%). CD133 expression demonstrated a strong significant association with patients exhibiting progressive disease when compared to CD90/CD326 expression (15 vs. 7.1%). CD133 may be significantly associated with invasion and metastatic spread of NSCLC. The co-expression of CD90, CD326 and CD133 has definite prognostic value in patients with NSCLC.

Deregulation of HOX B13 expression in urinary bladder cancer progression.

Urinary bladder cancer is a common malignancy in industrialized countries. More than 90% of bladder cancer originates in the transitional cells. Bladder transitional cancer prognosis is, according to the most recent definition related to the level of tumor infiltration, characterized by two main phenotypes, Non Muscle Invasive Bladder Transitional Cancer (NMIBC) and Muscle Invasive Bladder Transitional Cancer (MIBC). The genetic profile and the clinical course of the two subtypes are completely different, however among NMIBC the prognosis is not completely predictable, since 20% of the cases experience a relapse, even in the form of MIBC. It has recently been reported that the chromosomal region 12q13-15, containing crucial cancer genes such as MDM2, CDK4, GLI and an entire cluster of HOX genes, is amplified in bladder cancer. HOX genes codify for transcriptionl factor, involved in embryonal development and cancer progression, with main nuclear expression. Particularly it was also described the strong involvement of HOX B13 in several tumors of urogenital system. In this study we have been investigated, by immunohistochemisty and quantitative Real Time PCR, the HOX B13 expression in bladder cancer evolution and progression, evaluating its ability to discriminate between NMIBC and MBCI phenotypes. Cytoplasmic HOX B13 delocalization significantly relates with muscle invasion (p 0.004). In addition in the series of NMIBC nuclear HOX B13 expression loss is significantly associated to shorter disease free survival (p-value=0.038) defining a potential prognostic role. Overexpression of HOX B13 in more aggressive phenotype is also demonstrate at gene level by quantitative RT-PCR. The de-regulation and delocalization of HOX B13 in urinary bladder cancer supports again the important role of HOX genes in tumor evolution and represents a starting point to establish an integrated analysis, in which HOX genes represent important prognostic and predictive markers for bladder cancer.

The HOX genes network in uro-genital cancers: mechanisms and potential therapeutic implications.

Genito-urinary malignancies (prostate, bladder, renal and testicular cancers) rank high among human tumors with an incidence that varies with age and organ involvement. Prostate cancer is the most commonly detected male cancer followed by bladder and kidney cancers, less frequent in women. Testicular cancer, although rare, is the most frequent cancer in males under 35. The majority of oncogenic and tumor suppressor signaling pathways involved with urogenital cancers converge on sets of transcription factors that ultimately control gene expression resulting in tumor formation and metastatic progression. The activity of these transcription factors is modulated by multiple mechanisms spanning from transcriptional regulation, deregulation of the splicing, maturation, export and location of mRNAs, protein synthesis and post-translational modifications. The recent involvement of the epigenitic mechanisms in the generation and the evolution of cancer has produced a great deal of interest. This is related to the possibility that revealing these mechanisms able to regulate the cell memory program (the gene systems polycomb, trithorax and HOX) may generate important biological and therapeutic achievements. The HOX gene network is the only physically and functionally identifiable transcription factor network located in the human genome controlling crucial cellular processes. Here we describe the implication of the HOX genes in the urogenital embryonic development and cancers. We further highlight the mechanisms uncovered along these processes and involving the HOX genes. Finally, we foresee the specific targeting of HOX genes and in general the cell memory gene program in the therapeutic setting of urogenital malignancies due to their upstream location in these stepwise cell processes and their early deregulation in cancer evolution.

Parallel determination of NeuroD1, chromogranin-A, KI67 and androgen receptor expression in surgically treated prostate cancers.

PURPOSE: Neuroendocrine differentiation is a hallmark of prostate cancer. The aim of our study was the detection of the parallel expression of neuroendocrine related markers using a prostate tissue microarray (TMA). MATERIALS AND METHODS: Our study was aimed at detecting the parallel expression of NeuroD1, Chromogranin-A (ChrA), Androgen Receptor (AR) and Ki-67 by immunohistochemistry on prostate cancer tissue microarray. The data was analyzed using SAS version 8.2 (SAS Inc, Cary, NC). The relationships between NeuroD1, ChrA and AR expressions and patients' characteristics were investigated by multivariate logistic regression analysis. Progression and Overall Survival (OS) distributions were calculated using Kaplan-Meier method. RESULTS: Tissue reactivity for NeuroD1, ChrA and AR concerned 73%, 49% and 77% of the available cases, respectively. Regarding overall survival, there were 87 deaths and 295 patients alive/censored (6 years of median follow-up). Seventy-seven disease progressions occurred at the median follow-up 5.4y. A significant correlation between NeuroD1, ChrA and AR expression was observed (p < 0.001 and p < 0.03, respectively). Additionally, ChrA was strongly associated in multivariate analysis to Gleason score and Ki67 expression (p < 0.009 and p < 0.0052, respectively). Survival analysis showed no association between markers neither for overall nor for cancer-specific survival. CONCLUSIONS: The results highlight that NeuroD1, Chromogranin-A and Androgen Receptor are strongly associated, however their expression does not correlate with overall survival or disease progression.

Parallel determination of NeuroD1, Chromogranin-A, KI67 and androgen receptor expression in surgically treated prostate cancers

PURPOSE: Neuroendocrine differentiation is a hallmark of prostate cancer. The aim of our study was the detection of the parallel expression of neuroendocrine related markers using a prostate tissue microarray (TMA). MATERIALS AND METHODS: Our study was aimed at detecting the parallel expression of NeuroD1, Chromogranin-A (ChrA), Androgen Receptor (AR) and Ki-67 by immunohistochemistry on prostate cancer tissue microarray. The data was analyzed using SAS version 8.2 (SAS Inc, Cary, NC). The relationships between NeuroD1, ChrA and AR expressions and patients' characteristics were investigated by multivariate logistic regression analysis. Progression and Overall Survival (OS) distributions were calculated using Kaplan-Meier method. RESULTS: Tissue reactivity for NeuroD1, ChrA and AR concerned 73 percent, 49 percent and 77 percent of the available cases, respectively. Regarding overall survival, there were 87 deaths and 295 patients alive/censored (6 years of median follow-up). Seventy-seven disease progressions occurred at the median follow-up 5.4y. A significant correlation between NeuroD1, ChrA and AR expression was observed (p < 0.001 and p < 0.03, respectively). Additionally, ChrA was strongly associated in multivariate analysis to Gleason score and Ki67 expression (p < 0.009 and p < 0.0052, respectively). Survival analysis showed no association between markers neither for overall nor for cancer-specific survival. CONCLUSIONS: The results highlight that NeuroD1, Chromogranin-A and Androgen Receptor are strongly associated, however their expression does not correlate with overall survival or disease progression.

Homeobox genes in normal and abnormal vasculogenesis.

Homeobox containing genes are a family of transcription factors regulating normal development and controlling primary cellular processes (cell identity, cell division and differentiation) recently enriched by the discovery of their interaction with miRNAs and ncRNAs. Class I human homeobox genes (HOX genes) are characterized by a unique genomic network organization: four compact chromosomal loci where 39 sequence corresponding genes can be aligned with each other in 13 antero-posterior paralogous groups. The cardiovascular system is the first mesoderm organ-system to be generated during embryonic development; subsequently it generates the blood and lymphatic vascular systems. Cardiovascular remodelling is involved through homeobox gene regulation and deregulation in adult physiology (menstrual cycle and wound healing) and pathology (atherosclerosis, arterial restenosis, tumour angiogenesis and lymphangiogenesis). Understanding the role played by homeobox genes in endothelial and smooth muscle cell phenotype determination will be crucial in identifying the molecular processes involved in vascular cell differentiation, as well as to support future therapeutic strategies. We report here on the current knowledge of the role played by homeobox genes in normal and abnormal vasculogenesis and postulate a common molecular mechanism accounting for the involvement of homeobox genes in the regulation of the nuclear export of specific transcripts potentially capable of generating endothelial phenotype modification involved in new vessel formation.

cAMP induced modifications of HOX D gene expression in prostate cells allow the identification of a chromosomal area involved in vivo with neuroendocrine differentiation of human advanced prostate cancers.

The acquisition of epithelial-neuroendocrine differentiation (ND) is a peculiarity of human advanced, androgen-independent, prostate cancers. The HOX genes are a network of transcription factors controlling embryonal development and playing an important role in crucial adult eukaryotic cell functions. The molecular organization of this 39-gene network is unique in the genome and probably acts by regulating phenotype cell identity. The expression patterns of the HOX gene network in human prostate cell phenotypes, representing different stages of prostate physiology and prostate cancer progression, make it possible to discriminate between different human prostate cell lines and to identify loci and paralogous groups harboring the HOX genes mostly involved in prostate organogenesis and cancerogenesis. Exposure of prostate epithelial phenotypes to cAMP alters the expression of lumbo-sacral HOX D genes located on the chromosomal region 2q31-33 where the cAMP effector genes CREB1, CREB2, and cAMP-GEFII are present. Interestingly, this same chromosomal area harbors: (i) a global cis-regulatory DNA control region able to coordinate the expression of HOX D and contiguous phylogenetically unrelated genes; (ii) a prostate specific ncRNA gene associated with high-risk prostate cancer (PCGEM1); (iii) a series of neurogenic-related genes involved with epithelial-neuronal cell conversion. We report the expression of neurexin 1, Neuro D1, dlx1, and dlx2 in untreated and cAMP treated epithelial prostate cells. The in vivo expression of Neuro D1 in human advanced prostate cancers correlate with the state of tumor differentiation as measured by Gleason score. Thus, we suggest that the chromosomal area 2q 31-33 might be involved in the epithelial-ND characteristic of human advanced prostate cancers.

Pair-wise detection of eight common DNA polymorphisms of the human lipoprotein lipase gene by PCR-RFLP. Findings of the Olivetti Heart Study.

We developed a rapid procedure to analyse simultaneously two different DNA polymorphisms of the human LPL gene by PCR-RFLP (Polymerase Chain Reaction-Restriction Fragment Length Polymorphism). The method involves PCR amplification of the gene fragments encompassing two polymorphic sites, direct digestion in the same PCR-tube of the amplification mixture with two restriction enzymes, and the analysis of the resulting DNA fragments by gel electrophoresis. In 422 participants of the 1994 follow-up examination of the Olivetti Heart Study, a total of eight common LPL gene polymorphisms have been analysed in pairs by this procedure: -93 T/G and D9N; V108V and T361T; N291S and PvuII; HindIII and S447X. Two of these polymorphisms (V108V and T361T) were analysed for the first time. This method is suitable for the routine analysis of clinical samples of varying DNA content and practically halves the times and costs of screening for these LPL polymorphisms.

In vivo expression of the whole HOX gene network in human breast cancer.

The HOX network contains 39 genes that act as transcriptional regulators and control crucial cellular functions during both embryonic development and adult life. Inside the network, this is achieved according to the rules of temporal and spatial co-linearity with 3' HOX genes acting on the anterior part of the body, central HOX genes on the thoracic part and lumbo-sacral HOX genes on the caudal region. We analysed HOX gene expression in normal breast tissue and in primary breast cancers by reverse-transcriptase-polymerase chain reaction (RT-PCR). 17 out of 39 HOX genes were expressed in the normal breast tissue. The expression of thoracic HOX genes tended to be similar in normal and neoplastic breast tissues suggesting that these genes are involved in breast organogenesis. In contrast, cervical and lumbo-sacral HOX gene expression was altered in the primary breast cancers with respect to normal breast tissue. This supports their involvement in breast cancer evolution and suggests they could be targets for future cancer therapies.

[The cellular and molecular bases of "tooth framing"]. / Le basi cellulari e molecolari della "costruzione" dei denti.

Progress in molecular biology in recent years has enormously increased interest in tooth generation. The enamel knot has been discovered, in consequence. This is a transient structure acting as molecular signaling center, responsible for controlling cusp formation, stimulating growth of surrounding epithelium, and generating new knots or their disappearance through apoptosis. Both tooth development and enamel knots are regulated by a cascade of gene activity where Fgf4, Shh, BMP4, Lef1 and p21 are the prime movers of the processes. Homeobox genes (Msx, Dlx) are the orchestrators of the framing and a series of proteins (adhesion molecules, extracellular matrix components) are the executors of "tooth framing". An important concept has emerged from developmental biology through the identification of the basic mechanisms involved in tooth development: the molecular basis of structure framing shares common rules. Thus similar genetic programs are involved in body structure generation (limb bud, tooth, branching morphogenesis). A deeper understanding of developmental rules regulating tooth formation will make it possible in the near future: a) to modify in vivo homeobox gene expression and restore tooth generation hampered by tooth agenesia due to homeobox gene deregulation; b) to induce complete tooth formation, in case of tooth loss due to trauma or diseases, through implantation in the patient's oral cavity of a synthetic ball containing morphogens and growth factors to stimulate, in the right spatio-temporal sequence, the entire tooth genetic cascade. These concepts will certainly enforce cultural and practical interaction between biology and dentistry.

Not traditional prognostic factors in human conventional renal carcinoma.

The evaluation of know prognostic factors is an essential step of the assessment of the patients affected by primary renal carcinoma. As long as the major biological mechanisms of renal carcinomas remain unknown, it will be impossible to achieve an accurate prognostic judgement. The TNM classification has always been the main source of information. Nevertheless, recently several investigations evaluated the prognostic power of serum and cellular markers. The aim of this study is to identify those markers which show statistical reliability and can be used in the clinical practice. A literature search was performed on MEDLINE to identify potential not traditional prognostic factors for patients with renal cell carcinoma edited from January 1997 through April 2000 using prognosis and clear cell carcinoma and kidney as keywords. We considered also articles cited in references of first selected manuscript. The analysis of serum and cellular prognostic markers does not allow the identification of specific factors, reliable, independent, easy to dose, widely useful and whose informations are repeatable. Currently classical prognostic factors (staging, grading, hystologic type, patient clinical conditions, anaemia, presentation modalities, etc.) represent the only useful elements after surgical time in RCC patients. Among serum prognostic factors, CRP and ferritin play a crucial role. These proteins appear ideal in monitoring the disease over time, due to simple test execution and specimens repeatability. Among RCC molecular markers, proliferation index result promising for their reliability and reproducibility, the easy dosage and high series number tested. Literature data suggest that the ideal marker for renal carcinomas has not been identified yet. However, C-reactive protein, ferritin and the proliferative activity indexes (Ki67 and AgNOR) appear to be, at present, the best prognostic tools. To confirm obtained results and to use biomolecolar markers on a routinary base further studies on wide surgical series will be required. The improvement of technical tool and costs reduction represent also a necessary step toward the identification of efficient prognostic markers in RCC.

Homeobox genes in normal and malignant cells.

Homeobox genes are transcription factors primarily involved in embryonic development. Several homeobox gene families have so far been identified: Hox, EMX, PAX, MSX as well as many isolated divergent homeobox genes. Among these, Hox genes are most intriguing for having a regulatory network structure organization. Recent indications suggest the involvement of homeobox genes in (i) crucial adult eukariotic cell functions and (ii) human diseases, spanning from diabetes to cancer. In this review we will discuss the mechanisms through which homeobox genes act, and will propose a model for the function of the Hox gene network as decoding system for achieving specific genetic programs. New technologies for whole-genome RNA expression will be crucial to evaluate the clinical relevance of homeobox genes in structural and metabolic diseases.

Homeobox genes and cancer.

Homeobox-containing genes are a family of regulatory genes encoding transcription factors that primarily play a crucial role during development. Several indications suggest their involvement in the control of cell growth and, when dysregulated, in oncogenesis. We will describe the implications, in tumor origin and evolution, of members of the homeobox gene families HOX, EMX, PAX, and MSX as well as of other divergent homeobox genes. We will also propose a model for the function of the HOX gene network in controlling cell identity to account for the involvement of some HOX genes in both normal development and oncogenesis.

Differential patterns of HOX gene expression are associated with specific integrin and ICAM profiles in clonal populations isolated from a single human melanoma metastasis.

Homeobox-containing genes comprise a gene family coding for transcription factors involved in normal development. Class I human homeobox (HOX) genes display a peculiar chromosomal organization, perhaps directly related to their function. Aberrant expression of homeobox genes has been associated with both morphological abnormalities and oncogenesis. We have reported that HOX gene expression is (i) specific for normal adult human organs (kidney, colon, lung) and (ii) altered in cancer specimens according to their histological type and stage of tumor progression. Here, we have investigated whether patterns of HOX gene expression are associated with tumor heterogeneity by analyzing the expression of the entire panel of 38 HOX genes in clones isolated from a single human metastatic melanoma call line (Me 665/2). The differential expression of a block of genes located at the 5' end of the HOX C locus allows melanoma clones to be classified into 2 major groups. The 2 patterns of HOX gene expression are inversely associated with 2 distinct surface phenotypes for integrins (VLA-2, VLA-5 and VLA-6) and the adhesion molecule ICAM-1. The genes of the HOX C locus are silent in the clones with high levels of integrins VLA-2, VLA-5 and VLA-6 and of the adhesion molecule ICAM-1 but actively expressed in the clones with low levels of ICAM-1 and lacking VLA-2, VLA-5 and VLA-6. Our results indicate that HOX gene expression reflects the intra-tumor heterogeneity of melanoma clones and suggest that the expression of surface molecules involved in cell-cell and cell-matrix interactions may be related to the patterns of HOX gene expression.